Universal Journal of Environmental Research and Technology

Universal Journal of Environmental Research and Technology
All Rights Reserved Euresian Publications © 2011 eISSN 2249 0256
Available Online at: www.environmentaljournal.org
Volume 1, Issue 2: 212-215
Open Access
Short Communication
Analysis of Seasonal Variation of Indoor Radon Concentration in
Dwellings in Mitrovica, Kosova
1
2
3
3
1
* Besim Xhafa , Theodhor Karaja, Sadik Bekteshi, Skender Kabashi, Gezim Hodolli
1
Department of Medical Studies, University of Prishtina, Prishtina, Kosova
Faculty of Natural Sciences, Dept. of Physics. University of Tirana, Tirana, Albania
3
Faculty of Mathematical and Natural Sciences, Dept. of Physics. University of Prishtina, Prishtina, Kosova
2
*Corresponding author: [email protected]
Abstract:
The seasonal variation analysis of indoor radon concentration has been carried out in selected public
buildings in Mitrovica. Measurements were performed with Continuous Radon Monitor Model CRM-510.
Mitrovica has been chosen for this study since it is a post-industrial town in which many former industrial
objects are been used for other public purposes. According to the findings of this study the estimated annual
−3
average indoor radon concentration in the houses surveyed depend on season and ranges from 184.3 Bqm
−3
to 299.4 Bqm . Nevertheless, in particular, higher values of radon concentration have been found in Battery
−3
−3
Factory which range from 450.4 Bqm to 660.2 Bqm . The season/annual ratios for different type of
dwellings varied from 1.01 to 1.9. The mean annual estimated effective dose received by the residents of the
-1
−1
studied locations was estimated to be 1.60 mSvy . to 4.01 mSvy . The annual estimated effective dose is
close to the recommended action level.
Keywords: Indoor, seasonal measurement, radon, concentration, exposure dose, dwelling
1.0 Introduction:
Radon and its short-lived decay products in the
atmosphere are the most important contributors
to human exposure from natural sources. It is well
known that inhalation of the short-lived decay
products of 222 Rn (Radon), and to a lesser extent
the decay products of 220 Rn (Thoron), and their
subsequent deposition along the walls of the
various airways of the bronchial tree provide the
main pathway for radiation exposure of the lungs.
This exposure is mostly produced by the alpha
particles emitted by several of these radionuclide,
although some beta particles and gamma radiation
are also emitted (UNSCEAR 2000). The risk posed
by Radon is so high that only tobacco smoking is a
higher cause for lung cancer (USEPA, 2003).
Radon’s half-life of 3.8 day is long enough for it to
enter into the indoor environment and to cause an
increase in indoor concentrations, but it is
relatively too long to be inhaled into the
respiratory tract and to irradiate cells (Yuji Yamada
et al., 2006). The measuring units for Radon-222
are Bqm-3. Measuring the concentration of radon
was done in total of 17 rooms, and came up with
values which are between 119 Bqm-3 and 564
Bqm-3. In order to reduce the concentration of
radon, we have built a ventilation pump, and then
we performed repeated measurements and finally
came with results between 130-170 Bqm-3
Measurements were done during March, April and
December of 2009.
Although radon is used as a tracer in studying
movement of air and water masses on local and
global scales, as a tool in mineral exploration, as an
indicator of activity of fault zones and as an
earthquake precursor, we are mostly concerned
about its negative aspects. It has become clear
that, on the world wide average, breathing air
contaminated by radon and thoron contributes
more than half to the effective dose a member of
the general public receives from all natural
radioactive sources of ionizing radiation. (Janja
Vaupotic et al., 2008)
The city of Mitrovica is surrounded with mines of
Trepqa. These mines contain high level of Lead
which leads to many people being diagnosed with
lung cancer. The main purpose of this research is
to calculate the concentration of radon and take
the necessary steps in protecting and reducing the
number of people being affected by lung cancer as
a consequence of high concentration of radon on
the environment.
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Universal Journal of Environmental Research and Technology
o
2.0 Methods:
We only measured the level of Radon in public
buildings in the city of Mitrovica, which are
frequented by an average of 9500 people a day
altogether, mainly children. Measurements are
performed in different levels of buildings including:
undergrounds, ground floor, first and second floors
that have a maximum altitude of 10 m above the
surface of the earth. The level of Radon-222 was
measured using the following instrument;
Continuous Radon Monitor Model CRM-510 made
from FEMTO-TECH, INC. USA.
o
for this location are. Temperature 13 C-23 C,
Relative humidity 43%-56% and Atmospheric
pressure 85kPa-88kPa. After performing all these
procedures, we have gained the results for indoor
concentration of Radon in the air, and equivalent
dose.
3. 0 Results and Discussion:
Indoor air radon concentration is expressed in
-3
Bqm presented in the table 1.
Table1. Indoor Air Radon Concentration in Closed
Buildings in Mitrovica
CRn222 (Bqm
Sr.No.Place
Figure 1: Map of the Republic of Kosova
CRM-510 is a portable instrument and collects data
for four straight days in a ‘passive’ position. The
instrument does measurements of Rn-222 level,
and registered the temperature, relative humidity,
and atmospheric pressure. This instrument does
the records only the alpha particles.
Room
-3
)
Floor
March July December
279 245
295
1)
a
E. School
V-a
B
2)
a
E. School
VI-d
G
221 202
265
3)
a
E. School
III-a
G
234 212
253
4)
a
E. School
IX-c
I
202 176.2
119
5)
Gymnasium
10-a
B
270 262
285
6)
Gymnasium
11-c
G
293 290
299
7)
Gymnasium
11-f
G
260 255
263
8)
Gymnasium
12-a
I
248 240
280
9)
Kindergarten Room-1 B
260 235
287
10)
Kindergarten Room-3 G
206 184.3
218
11)
Kindergarten Room-5 G
231 221
243
12)
Kindergarten Kitchen
I
198 180
208
13)
b
B
643 650
664
14)
B. Factory
B
623 638
660
15)
B. Factory
G
563 550
570
16)
B. Factory
I
495 499
409
17)
B. Factory
II
450 457
492
B. Factory
Room
A1
Room
A2
Room
B1
Room
C5
Room
C7
B = basement, G = ground floor, I = first floor, II =
a
Second floor, E. Scholl = Elementary School
b
‘Migjeni’, B. Factory = Battery Factory.
Figure 2: Radon Monitor Model CRM-510
CRM-510 was placed at 1-1.5 meter height, and
30–40 cm distance from walls, the measured of
Radon concentration for 24 straight hours and a
specified position. In order to better elaborate the
results, we take in consideration the temperature,
relative humidity and atmospheric pressure, which
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Universal Journal of Environmental Research and Technology
The distribution of radon concentration is showed
in figure3. Average values of radon concentration
and Average Equivalent dose for each building
showed in table II.
DCFRn: Dose conversion factor for radon (=9
nSv/h/Bq-m3).
Figure 3: The distribution of radon concentration in
closed buildings for each month in Mitrovica. (The
numbers on the horizontal axis are the same as in
table 1)
Figure 4: Average Values of Equivalent Dose for
each Building
If we compare the average values of the premises, it
thus appears that these values are smaller than the
values allowed by the ICRP. According to the ICRP
(International
Commission
on
Radiological
Protection) the value 600 Bqm-3 should not be
passed for a closed space (Vaupotic, 2003). Also in
addition dwelling constructed after 1980 seem to
present higher average radon concentration than
older constructed dwelling (Manousakas et al. 2010).
226
It is attributed to the higher Ra content to cement
used for concrete production, due to the addition of
fly ash (Papaefthymiou and Gouserti, 2008).
Table 2: Average values of radon concentration
and Average Equivalent dose for each building
Buildings
Average value of
Radon contraction
E. School
Gymnasium
Kindergarten
B. Factory
225.66
270.40
222.60
557.50
Bq ⋅ m
−3
Equivalent
Dose mSv/yr
1.62
1.94
1.60
4.01
The effective dose caused by exposure to the
decay products of radon was estimated using the
following equations:
H Rn = EERC ⋅ t ⋅ DCFRn
Approximately same results are presented in paper
of Jing Chen (2010) and Karpinska et al. (2004). In
this study, EERC was calculated using an
equilibrium factor of 0.4 for radon. The dose
conversion factors DCFRn and EERC are provided
by the UNSCEAR report (UNSCEAR, 2000). Example
we can calculate using the data shown in first row
(average value) of Table II. Average of values of
radon concentration and Equivalent dose for each
building, the effective dose in indoor environments
was estimated to be 1.62 mSv/yr (=225.66 ⋅ 0.4 ⋅
2000 ⋅ 9/1,000,000) for radon decay products. The
distribution of average equivalent dose is showed
in figure 4.
4. Conclusion:
Indoor air radon (222Rn) concentrations obtained
in March, July and December in 17 rooms. Average
values were calculated both independently from
each other, and also a total average value was
derived for all buildings together. The average
value of radon in Elementary school “Migjeni” is
225.66 Bqm-3, and equivalent dose is 1.62 mSv/yr,
in Gymnasium the radon is 270.4 Bqm-3, the
equivalent dose is 1.64 mSv/yr in Kindergarten the
value of radon is 222.6 Bqm-3, the equivalent dose
is 1.60 mSv/yr and in the Factory of Battery the
average value is 557,50 Bqm-3, and the dose is
4.01 mSv/yr.
(0.1)
Where:
HRn: Annual effective dose for radon decay
products (mSv/yr).
EERC: Equilibrium equivalent radon concentration
(Bq/m3).
t: Time in hours of indoor exposure in a year
(=2000 h).
The main purpose of these measurements was to
determine the concentration of radon in the
above-mentioned buildings, but especially Factory
of Battery. The workers in this building where
spend a good amount of time. It was essential to
let the staff know about these values and take the
needed steps to prevent any health complication.
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Universal Journal of Environmental Research and Technology
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1.
2.
3.
4.
5.
6.
7.
8
9
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